2016-09-23 20:48:37 +00:00
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.. _flow_modules:
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2018-02-13 15:23:55 +00:00
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===========================
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Ansible Module Architecture
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===========================
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2016-09-23 20:48:37 +00:00
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This in-depth dive helps you understand Ansible's program flow to execute
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modules. It is written for people working on the portions of the Core Ansible
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Engine that execute a module. Those writing Ansible Modules may also find this
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in-depth dive to be of interest, but individuals simply using Ansible Modules
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will not likely find this to be helpful.
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.. _flow_types_of_modules:
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Types of Modules
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================
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Ansible supports several different types of modules in its code base. Some of
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these are for backwards compatibility and others are to enable flexibility.
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.. _flow_action_plugins:
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Action Plugins
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--------------
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Action Plugins look like modules to end users who are writing :term:`playbooks` but
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they're distinct entities for the purposes of this document. Action Plugins
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always execute on the controller and are sometimes able to do all work there
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(for instance, the ``debug`` Action Plugin which prints some text for the user to
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see or the ``assert`` Action Plugin which can test whether several values in
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a playbook satisfy certain criteria.)
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More often, Action Plugins set up some values on the controller, then invoke an
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actual module on the managed node that does something with these values. An
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easy to understand version of this is the :ref:`template Action Plugin
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<template>`. The :ref:`template Action Plugin <template>` takes values from
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the user to construct a file in a temporary location on the controller using
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variables from the playbook environment. It then transfers the temporary file
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to a temporary file on the remote system. After that, it invokes the
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:ref:`copy module <copy>` which operates on the remote system to move the file
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into its final location, sets file permissions, and so on.
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.. _flow_new_style_modules:
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New-style Modules
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-----------------
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All of the modules that ship with Ansible fall into this category.
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New-style modules have the arguments to the module embedded inside of them in
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some manner. Non-new-style modules must copy a separate file over to the
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managed node, which is less efficient as it requires two over-the-wire
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connections instead of only one.
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.. _flow_python_modules:
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Python
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^^^^^^
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New-style Python modules use the :ref:`Ansiballz` framework for constructing
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modules. All official modules (shipped with Ansible) use either this or the
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:ref:`powershell module framework <flow_powershell_modules>`.
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These modules use imports from :code:`ansible.module_utils` in order to pull in
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boilerplate module code, such as argument parsing, formatting of return
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values as :term:`JSON`, and various file operations.
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.. note:: In Ansible, up to version 2.0.x, the official Python modules used the
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:ref:`module_replacer` framework. For module authors, :ref:`Ansiballz` is
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largely a superset of :ref:`module_replacer` functionality, so you usually
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do not need to know about one versus the other.
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.. _flow_powershell_modules:
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Powershell
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^^^^^^^^^^
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New-style powershell modules use the :ref:`module_replacer` framework for
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constructing modules. These modules get a library of powershell code embedded
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in them before being sent to the managed node.
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.. _flow_jsonargs_modules:
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JSONARGS
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^^^^^^^^
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Scripts can arrange for an argument string to be placed within them by placing
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the string ``<<INCLUDE_ANSIBLE_MODULE_JSON_ARGS>>`` somewhere inside of the
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2017-01-07 19:38:52 +00:00
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file. The module typically sets a variable to that value like this:
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.. code-block:: python
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2016-09-23 20:48:37 +00:00
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json_arguments = """<<INCLUDE_ANSIBLE_MODULE_JSON_ARGS>>"""
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2017-01-07 19:38:52 +00:00
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Which is expanded as:
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.. code-block:: python
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2016-09-23 20:48:37 +00:00
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json_arguments = """{"param1": "test's quotes", "param2": "\"To be or not to be\" - Hamlet"}"""
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.. note:: Ansible outputs a :term:`JSON` string with bare quotes. Double quotes are
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used to quote string values, double quotes inside of string values are
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backslash escaped, and single quotes may appear unescaped inside of
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a string value. To use JSONARGS, your scripting language must have a way
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to handle this type of string. The example uses Python's triple quoted
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strings to do this. Other scripting languages may have a similar quote
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character that won't be confused by any quotes in the JSON or it may
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allow you to define your own start-of-quote and end-of-quote characters.
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If the language doesn't give you any of these then you'll need to write
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a :ref:`non-native JSON module <flow_want_json_modules>` or
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:ref:`Old-style module <flow_old_style_modules>` instead.
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The module typically parses the contents of ``json_arguments`` using a JSON
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library and then use them as native variables throughout the rest of its code.
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.. _flow_want_json_modules:
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Non-native want JSON modules
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----------------------------
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If a module has the string ``WANT_JSON`` in it anywhere, Ansible treats
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it as a non-native module that accepts a filename as its only command line
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parameter. The filename is for a temporary file containing a :term:`JSON`
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string containing the module's parameters. The module needs to open the file,
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read and parse the parameters, operate on the data, and print its return data
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as a JSON encoded dictionary to stdout before exiting.
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These types of modules are self-contained entities. As of Ansible 2.1, Ansible
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only modifies them to change a shebang line if present.
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.. seealso:: Examples of Non-native modules written in ruby are in the `Ansible
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for Rubyists <https://github.com/ansible/ansible-for-rubyists>`_ repository.
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.. _flow_binary_modules:
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Binary Modules
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--------------
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From Ansible 2.2 onwards, modules may also be small binary programs. Ansible
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doesn't perform any magic to make these portable to different systems so they
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may be specific to the system on which they were compiled or require other
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binary runtime dependencies. Despite these drawbacks, a site may sometimes
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have no choice but to compile a custom module against a specific binary
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library if that's the only way they have to get access to certain resources.
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Binary modules take their arguments and will return data to Ansible in the same
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way as :ref:`want JSON modules <flow_want_json_modules>`.
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.. seealso:: One example of a `binary module
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2016-12-30 09:53:36 +00:00
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<https://github.com/ansible/ansible/blob/devel/test/integration/targets/binary_modules/library/helloworld.go>`_
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2016-09-23 20:48:37 +00:00
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written in go.
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.. _flow_old_style_modules:
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Old-style Modules
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-----------------
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Old-style modules are similar to
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:ref:`want JSON modules <flow_want_json_modules>`, except that the file that
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they take contains ``key=value`` pairs for their parameters instead of
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:term:`JSON`.
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Ansible decides that a module is old-style when it doesn't have any of the
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markers that would show that it is one of the other types.
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.. _flow_how_modules_are_executed:
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How modules are executed
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========================
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When a user uses :program:`ansible` or :program:`ansible-playbook`, they
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specify a task to execute. The task is usually the name of a module along
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with several parameters to be passed to the module. Ansible takes these
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values and processes them in various ways before they are finally executed on
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the remote machine.
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.. _flow_executor_task_executor:
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executor/task_executor
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----------------------
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The TaskExecutor receives the module name and parameters that were parsed from
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the :term:`playbook <playbooks>` (or from the command line in the case of
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:command:`/usr/bin/ansible`). It uses the name to decide whether it's looking
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at a module or an :ref:`Action Plugin <flow_action_plugins>`. If it's
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a module, it loads the :ref:`Normal Action Plugin <flow_normal_action_plugin>`
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and passes the name, variables, and other information about the task and play
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to that Action Plugin for further processing.
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.. _flow_normal_action_plugin:
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Normal Action Plugin
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--------------------
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The ``normal`` Action Plugin executes the module on the remote host. It is
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the primary coordinator of much of the work to actually execute the module on
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the managed machine.
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* It takes care of creating a connection to the managed machine by
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instantiating a ``Connection`` class according to the inventory
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configuration for that host.
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* It adds any internal Ansible variables to the module's parameters (for
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instance, the ones that pass along ``no_log`` to the module).
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* It takes care of creating any temporary files on the remote machine and
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cleans up afterwards.
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* It does the actual work of pushing the module and module parameters to the
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remote host, although the :ref:`module_common <flow_executor_module_common>`
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code described in the next section does the work of deciding which format
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those will take.
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* It handles any special cases regarding modules (for instance, various
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complications around Windows modules that must have the same names as Python
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modules, so that internal calling of modules from other Action Plugins work.)
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Much of this functionality comes from the :class:`BaseAction` class,
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which lives in :file:`plugins/action/__init__.py`. It makes use of
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``Connection`` and ``Shell`` objects to do its work.
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.. note::
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When :term:`tasks <tasks>` are run with the ``async:`` parameter, Ansible
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uses the ``async`` Action Plugin instead of the ``normal`` Action Plugin
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to invoke it. That program flow is currently not documented. Read the
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source for information on how that works.
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.. _flow_executor_module_common:
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executor/module_common.py
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-------------------------
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Code in :file:`executor/module_common.py` takes care of assembling the module
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to be shipped to the managed node. The module is first read in, then examined
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to determine its type. :ref:`PowerShell <flow_powershell_modules>` and
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:ref:`JSON-args modules <flow_jsonargs_modules>` are passed through
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:ref:`Module Replacer <module_replacer>`. New-style
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:ref:`Python modules <flow_python_modules>` are assembled by :ref:`Ansiballz`.
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:ref:`Non-native-want-JSON <flow_want_json_modules>`,
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:ref:`Binary modules <flow_binary_modules>`, and
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:ref:`Old-Style modules <flow_old_style_modules>` aren't touched by either of
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these and pass through unchanged. After the assembling step, one final
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modification is made to all modules that have a shebang line. Ansible checks
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whether the interpreter in the shebang line has a specific path configured via
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an ``ansible_$X_interpreter`` inventory variable. If it does, Ansible
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substitutes that path for the interpreter path given in the module. After
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this, Ansible returns the complete module data and the module type to the
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:ref:`Normal Action <flow_normal_action_plugin>` which continues execution of
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the module.
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Next we'll go into some details of the two assembler frameworks.
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.. _module_replacer:
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Module Replacer
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^^^^^^^^^^^^^^^
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The Module Replacer framework is the original framework implementing new-style
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modules. It is essentially a preprocessor (like the C Preprocessor for those
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familiar with that programming language). It does straight substitutions of
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specific substring patterns in the module file. There are two types of
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substitutions:
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* Replacements that only happen in the module file. These are public
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replacement strings that modules can utilize to get helpful boilerplate or
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access to arguments.
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- :code:`from ansible.module_utils.MOD_LIB_NAME import *` is replaced with the
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contents of the :file:`ansible/module_utils/MOD_LIB_NAME.py` These should
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only be used with :ref:`new-style Python modules <flow_python_modules>`.
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- :code:`#<<INCLUDE_ANSIBLE_MODULE_COMMON>>` is equivalent to
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:code:`from ansible.module_utils.basic import *` and should also only apply
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to new-style Python modules.
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- :code:`# POWERSHELL_COMMON` substitutes the contents of
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:file:`ansible/module_utils/powershell.ps1`. It should only be used with
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:ref:`new-style Powershell modules <flow_powershell_modules>`.
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* Replacements that are used by ``ansible.module_utils`` code. These are internal
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replacement patterns. They may be used internally, in the above public
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replacements, but shouldn't be used directly by modules.
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- :code:`"<<ANSIBLE_VERSION>>"` is substituted with the Ansible version. In
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:ref:`new-style Python modules <flow_python_modules>` under the
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2017-10-02 13:45:18 +00:00
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:ref:`Ansiballz` framework the proper way is to instead instantiate an
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2016-09-23 20:48:37 +00:00
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:class:`AnsibleModule` and then access the version from
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:attr:``AnsibleModule.ansible_version``.
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- :code:`"<<INCLUDE_ANSIBLE_MODULE_COMPLEX_ARGS>>"` is substituted with
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a string which is the Python ``repr`` of the :term:`JSON` encoded module
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parameters. Using ``repr`` on the JSON string makes it safe to embed in
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a Python file. In new-style Python modules under the Ansiballz framework
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this is better accessed by instantiating an :class:`AnsibleModule` and
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then using :attr:`AnsibleModule.params`.
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- :code:`<<SELINUX_SPECIAL_FILESYSTEMS>>` substitutes a string which is
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a comma separated list of file systems which have a file system dependent
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security context in SELinux. In new-style Python modules, if you really
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need this you should instantiate an :class:`AnsibleModule` and then use
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:attr:`AnsibleModule._selinux_special_fs`. The variable has also changed
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from a comma separated string of file system names to an actual python
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list of filesystem names.
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- :code:`<<INCLUDE_ANSIBLE_MODULE_JSON_ARGS>>` substitutes the module
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parameters as a JSON string. Care must be taken to properly quote the
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string as JSON data may contain quotes. This pattern is not substituted
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in new-style Python modules as they can get the module parameters another
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way.
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- The string :code:`syslog.LOG_USER` is replaced wherever it occurs with the
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``syslog_facility`` which was named in :file:`ansible.cfg` or any
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``ansible_syslog_facility`` inventory variable that applies to this host. In
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new-style Python modules this has changed slightly. If you really need to
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access it, you should instantiate an :class:`AnsibleModule` and then use
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:attr:`AnsibleModule._syslog_facility` to access it. It is no longer the
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actual syslog facility and is now the name of the syslog facility. See
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the :ref:`documentation on internal arguments <flow_internal_arguments>`
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for details.
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.. _Ansiballz:
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Ansiballz
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^^^^^^^^^
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Ansible 2.1 switched from the :ref:`module_replacer` framework to the
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Ansiballz framework for assembling modules. The Ansiballz framework differs
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from module replacer in that it uses real Python imports of things in
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:file:`ansible/module_utils` instead of merely preprocessing the module. It
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does this by constructing a zipfile -- which includes the module file, files
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in :file:`ansible/module_utils` that are imported by the module, and some
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boilerplate to pass in the module's parameters. The zipfile is then Base64
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encoded and wrapped in a small Python script which decodes the Base64 encoding
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and places the zipfile into a temp directory on the managed node. It then
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extracts just the ansible module script from the zip file and places that in
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the temporary directory as well. Then it sets the PYTHONPATH to find python
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modules inside of the zip file and invokes :command:`python` on the extracted
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ansible module.
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.. note::
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Ansible wraps the zipfile in the Python script for two reasons:
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2017-03-17 01:49:29 +00:00
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* for compatibility with Python-2.6 which has a less
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functional version of Python's ``-m`` command line switch.
|
2016-09-23 20:48:37 +00:00
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* so that pipelining will function properly. Pipelining needs to pipe the
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Python module into the Python interpreter on the remote node. Python
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understands scripts on stdin but does not understand zip files.
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In Ansiballz, any imports of Python modules from the
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:py:mod:`ansible.module_utils` package trigger inclusion of that Python file
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into the zipfile. Instances of :code:`#<<INCLUDE_ANSIBLE_MODULE_COMMON>>` in
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the module are turned into :code:`from ansible.module_utils.basic import *`
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and :file:`ansible/module-utils/basic.py` is then included in the zipfile.
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Files that are included from :file:`module_utils` are themselves scanned for
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imports of other Python modules from :file:`module_utils` to be included in
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the zipfile as well.
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.. warning::
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At present, the Ansiballz Framework cannot determine whether an import
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should be included if it is a relative import. Always use an absolute
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import that has :py:mod:`ansible.module_utils` in it to allow Ansiballz to
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determine that the file should be included.
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.. _flow_passing_module_args:
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Passing args
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~~~~~~~~~~~~
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In :ref:`module_replacer`, module arguments are turned into a JSON-ified
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string and substituted into the combined module file. In :ref:`Ansiballz`,
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the JSON-ified string is passed into the module via stdin. When
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a :class:`ansible.module_utils.basic.AnsibleModule` is instantiated,
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it parses this string and places the args into
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:attr:`AnsibleModule.params` where it can be accessed by the module's
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|
other code.
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.. note::
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Internally, the :class:`AnsibleModule` uses the helper function,
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:py:func:`ansible.module_utils.basic._load_params`, to load the parameters
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from stdin and save them into an internal global variable. Very dynamic
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custom modules which need to parse the parameters prior to instantiating
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an ``AnsibleModule`` may use ``_load_params`` to retrieve the
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parameters. Be aware that ``_load_params`` is an internal function and
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may change in breaking ways if necessary to support changes in the code.
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However, we'll do our best not to break it gratuitously, which is not
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something that can be said for either the way parameters are passed or
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the internal global variable.
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.. _flow_internal_arguments:
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Internal arguments
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^^^^^^^^^^^^^^^^^^
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Both :ref:`module_replacer` and :ref:`Ansiballz` send additional arguments to
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the module beyond those which the user specified in the playbook. These
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additional arguments are internal parameters that help implement global
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|
Ansible features. Modules often do not need to know about these explicitly as
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the features are implemented in :py:mod:`ansible.module_utils.basic` but certain
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features need support from the module so it's good to know about them.
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_ansible_no_log
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~~~~~~~~~~~~~~~
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This is a boolean. If it's True then the playbook specified ``no_log`` (in
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a task's parameters or as a play parameter). This automatically affects calls
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to :py:meth:`AnsibleModule.log`. If a module implements its own logging then
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|
it needs to check this value. The best way to look at this is for the module
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|
to instantiate an :class:`AnsibleModule` and then check the value of
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:attr:`AnsibleModule.no_log`.
|
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|
.. note::
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``no_log`` specified in a module's argument_spec are handled by a different mechanism.
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_ansible_debug
|
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~~~~~~~~~~~~~~
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|
This is a boolean that turns on more verbose logging. If a module uses
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:py:meth:`AnsibleModule.debug` rather than :py:meth:`AnsibleModule.log` then
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|
the messages are only logged if this is True. This also turns on logging of
|
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|
|
external commands that the module executes. This can be changed via
|
2017-01-03 06:48:33 +00:00
|
|
|
the ``debug`` setting in :file:`ansible.cfg` or the environment variable
|
2016-09-23 20:48:37 +00:00
|
|
|
:envvar:`ANSIBLE_DEBUG`. If, for some reason, a module must access this, it
|
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|
should do so by instantiating an :class:`AnsibleModule` and accessing
|
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|
:attr:`AnsibleModule._debug`.
|
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|
_ansible_diff
|
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|
~~~~~~~~~~~~~
|
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|
|
This boolean is turned on via the ``--diff`` command line option. If a module
|
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|
|
supports it, it will tell the module to show a unified diff of changes to be
|
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|
|
made to templated files. The proper way for a module to access this is by
|
|
|
|
instantiating an :class:`AnsibleModule` and accessing
|
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|
|
:attr:`AnsibleModule._diff`.
|
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|
|
|
|
_ansible_verbosity
|
|
|
|
~~~~~~~~~~~~~~~~~~
|
|
|
|
|
|
|
|
This value could be used for finer grained control over logging. However, it
|
|
|
|
is currently unused.
|
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|
|
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|
|
|
_ansible_selinux_special_fs
|
|
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
|
|
|
|
This is a list of names of filesystems which should have a special selinux
|
|
|
|
context. They are used by the :class:`AnsibleModule` methods which operate on
|
|
|
|
files (changing attributes, moving, and copying). The list of names is set
|
|
|
|
via a comma separated string of filesystem names from :file:`ansible.cfg`::
|
|
|
|
|
|
|
|
# ansible.cfg
|
|
|
|
[selinux]
|
|
|
|
special_context_filesystems=nfs,vboxsf,fuse,ramfs
|
|
|
|
|
|
|
|
If a module cannot use the builtin ``AnsibleModule`` methods to manipulate
|
|
|
|
files and needs to know about these special context filesystems, it should
|
|
|
|
instantiate an ``AnsibleModule`` and then examine the list in
|
|
|
|
:attr:`AnsibleModule._selinux_special_fs`.
|
|
|
|
|
|
|
|
This replaces :attr:`ansible.module_utils.basic.SELINUX_SPECIAL_FS` from
|
|
|
|
:ref:`module_replacer`. In module replacer it was a comma separated string of
|
|
|
|
filesystem names. Under Ansiballz it's an actual list.
|
|
|
|
|
|
|
|
.. versionadded:: 2.1
|
|
|
|
|
|
|
|
_ansible_syslog_facility
|
|
|
|
~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
|
|
|
|
This parameter controls which syslog facility ansible module logs to. It may
|
|
|
|
be set by changing the ``syslog_facility`` value in :file:`ansible.cfg`. Most
|
|
|
|
modules should just use :meth:`AnsibleModule.log` which will then make use of
|
|
|
|
this. If a module has to use this on its own, it should instantiate an
|
|
|
|
:class:`AnsibleModule` and then retrieve the name of the syslog facility from
|
|
|
|
:attr:`AnsibleModule._syslog_facility`. The code will look slightly different
|
2017-01-06 20:33:00 +00:00
|
|
|
than it did under :ref:`module_replacer` due to how hacky the old way was
|
|
|
|
|
2017-01-07 19:38:52 +00:00
|
|
|
.. code-block:: python
|
2016-09-23 20:48:37 +00:00
|
|
|
|
|
|
|
# Old way
|
|
|
|
import syslog
|
|
|
|
syslog.openlog(NAME, 0, syslog.LOG_USER)
|
|
|
|
|
|
|
|
# New way
|
|
|
|
import syslog
|
|
|
|
facility_name = module._syslog_facility
|
|
|
|
facility = getattr(syslog, facility_name, syslog.LOG_USER)
|
|
|
|
syslog.openlog(NAME, 0, facility)
|
|
|
|
|
|
|
|
.. versionadded:: 2.1
|
|
|
|
|
|
|
|
_ansible_version
|
|
|
|
~~~~~~~~~~~~~~~~
|
|
|
|
|
|
|
|
This parameter passes the version of ansible that runs the module. To access
|
|
|
|
it, a module should instantiate an :class:`AnsibleModule` and then retrieve it
|
|
|
|
from :attr:`AnsibleModule.ansible_version`. This replaces
|
|
|
|
:attr:`ansible.module_utils.basic.ANSIBLE_VERSION` from
|
|
|
|
:ref:`module_replacer`.
|
|
|
|
|
|
|
|
.. versionadded:: 2.1
|
|
|
|
|
|
|
|
.. _flow_special_considerations:
|
|
|
|
|
|
|
|
Special Considerations
|
|
|
|
----------------------
|
|
|
|
|
|
|
|
.. _flow_pipelining:
|
|
|
|
|
|
|
|
Pipelining
|
|
|
|
^^^^^^^^^^
|
|
|
|
|
|
|
|
Ansible can transfer a module to a remote machine in one of two ways:
|
|
|
|
|
|
|
|
* it can write out the module to a temporary file on the remote host and then
|
|
|
|
use a second connection to the remote host to execute it with the
|
|
|
|
interpreter that the module needs
|
|
|
|
* or it can use what's known as pipelining to execute the module by piping it
|
|
|
|
into the remote interpreter's stdin.
|
|
|
|
|
|
|
|
Pipelining only works with modules written in Python at this time because
|
|
|
|
Ansible only knows that Python supports this mode of operation. Supporting
|
|
|
|
pipelining means that whatever format the module payload takes before being
|
|
|
|
sent over the wire must be executable by Python via stdin.
|
|
|
|
|
|
|
|
.. _flow_args_over_stdin:
|
|
|
|
|
|
|
|
Why pass args over stdin?
|
|
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
|
|
|
|
Passing arguments via stdin was chosen for the following reasons:
|
|
|
|
|
|
|
|
* When combined with :ref:`pipelining`, this keeps the module's arguments from
|
|
|
|
temporarily being saved onto disk on the remote machine. This makes it
|
|
|
|
harder (but not impossible) for a malicious user on the remote machine to
|
|
|
|
steal any sensitive information that may be present in the arguments.
|
|
|
|
* Command line arguments would be insecure as most systems allow unprivileged
|
|
|
|
users to read the full commandline of a process.
|
|
|
|
* Environment variables are usually more secure than the commandline but some
|
|
|
|
systems limit the total size of the environment. This could lead to
|
|
|
|
truncation of the parameters if we hit that limit.
|
|
|
|
|